Using KConfig XT

This tutorial introduces the main concepts of the KconfigXT
configuration framework and shows how to efficiently use it in applications. It assumes that the reader has already developed a KDE application and is familiar with KConfig. A basic understanding of XML and concepts behind DTDs is also required.

The main idea behind KConfig XT is to make the life of application developers
easier while making the administration of large KDE installations more manageable.
The four basic parts of the new framework are:

KConfigSkeleton - a class in the libkdecore library which grants a more flexible access to the configuration options,

An ini like file which provides the code generation options (the .kcfgc file)

kconfig_compiler - which generates C++ source code from .kcfg and .kcfgc files. The generated class is based on KConfigSkeleton and provides an API for the application to access its configuration data.

Note

In this tutorial more advanced and optional features of KConfig XT and their descriptions are marked by italic text. If you decide to skip them during the first reading, be sure to come back to them at some point.

.kcfg DTD Structure

The structure of the .kcfg file is described by its DTD (kcfg.xsd - available from
here (please note that browsers do not display DTDs in a visual form,
download the DTD directly and view it like a text file) or the kdecore
library). Please go through it before you go any further.

Lets create a simple .kcfg file. Please reference the code below as we go through each step.

Use your favorite code editor to open a your_application_name.kcfg file (of course replacing your_application_name with the name of the application you want to convert to KConfig XT).

Start that file by opening the <kcfgfile> tag which controls which KConfig file the data will be stored in. There are three possibilities:

If the <kcfgfile> tag has no attributes the generated code will use the application's default KConfig file (normally $HOME/.kde/config/<appname>rc).

The "name" attribute is used to manually specify a file name. If the value assigned to "name" is not an absolute file path, the file will be created in the default KDE config directory (normally $HOME/.kde/config).

If you would like to be able to specify the config file at construction time, use <kcfgfile arg="true">. This causes the constructor of the generated class to take a KSharedConfig::Ptr as an argument, allowing you to construct multiple instances pointing to different files.

Add the optional <include> tags which may contain C++ header files that are needed to compile the code required to compute the default values.

The remaining entries in the XML file are grouped by the tag <group> which describes the corresponding groups in the configuration file.

The individual entries must have at least a name or a key. The key is used as the key in the config file. The name is used to create accessor and modifier functions. If <key> is not given, the name is used as the config file key. If <key> is given, but not <name>, the name is constructed by removing all spaces from the <key> contents.

Always add a label or a whatsthis tags to your application in which you describe the configuration options. The label tag is used for short descriptions of the entry, while whatsthis contains more verbose documentation. It's important for tools like KConfigEditor which can be used by systems administrators to setup machines over on the network.

An entry must also have a type. The allowed types are: String, StringList, Font, Rect, Size, Color, Point, Int, UInt, Bool, Double, DateTime, Int64, UInt64 and Password. Besides those basic type the following special types are supported and include:

Path - This is a string that is specially treated as a file-path. In particular paths in the home directory are prefixed with $HOME when being stored in the configuration file.

Enum - This indicates an enumeration. The possible enum values should be provided via the <choices> tag. Enum values are accessed as integers by the application but stored as string in the configuration file. This makes it possible to add more values at a later date without breaking compatibility.

IntList - This indicates a list of integers. This information is provided to the application as QValueList<int>. Useful for storing QSplitter geometries.

PathList - List of Path elements.

The min and max tags can be set to limit the value of the integer-type options.

An entry can optionally have a default value which is used as default when the value isn't specified in any config file. Default values are interpreted as literal constant values. If a default value needs to be computed or if it needs to be obtained from a function call, the <default> tag should contain the code="true" attribute. The contents of the <default> tag is then considered to be a C++ expression.

Additional code for computing default values can be provided via the <code> tag. The contents of the <code> tag is inserted as-is. A typical use for this is to compute a common default value which can then be referenced by multiple entries that follow.

Optionally, the hidden option can also be added to the <entry>. The possible values are true and false.

.kcfgc files

After creating a .kcfg file create a .kcfgc file which describes the C++ file
generation options. The .kcfgc file is a simple ini file with the typical
"entry=value" format. To create a simple .kcfgc file follow these steps:

Open a new file in your favorite text editor.

Start it with the "File=your_application_name.kcfg" entry which specifies where the configuration options for your application are stored.

Add the "ClassName=YourConfigClassName" entry which specifies the name of the class that will be generated from the .kcfg file. Remember that the generated class will be derived from KConfigSkeleton. PLease make sure that YourConfigClassName is not a class name already used in your application. Save this file under yourconfigclassname.kcfgc. This will ensure the generation of the yourconfigclassname.{h,cpp} files where your configuration class will reside.

NameSpace - specifies the namespace in which the generated config class should reside,

Inherits - if you need the generated class to inherit your custom class,

Singleton - if the configuration class should be a singleton,

MemberVariables - specifies the access to the member variables, default is private,

ItemAccessors - relates to the above item, if member variables are public then it might make little sense to generate accessors. By default they are generated,

Mutators - similar to the above one, but applies to the mutator methods,

GlobalEnums - specifies whether enums should be class wide of whether they should be always explicitly prefixed with their type name,

UseEnumTypes - specifies whether enum values should be passed as type int or as their enum type in the return value of accessor functions and the arguments of mutator and signal functions.

Adjusting the CMakeLists.txt file

After creating the .kcfg and .kcfgc files the next step is to adjust the
build to let kconfig_compiler generate the required class at compile time. Fortunately doing this is trivial and requires only one step, adding this line to the CMakeLists.txt file example:

kde4_add_kcfg_files(<project name>_SRCS settings.kcfgc)

Alternatively, if a .moc file needs to be generated before compiling the generated source code, use

kde4_add_kcfg_files(<project name>_SRCS GENERATE_MOC settings.kcfgc)

This assures that the configuration class is properly generated and that the .kcfg is installed so it can be used by tools like
the KConfigEditor.

Use and Dialogs

After making all of the above changes you're ready to use KConfig XT. The
kconfig_compiler generated header file will have the name equal to the name of the .kcfg file but with a ".h" extension. Simply include that file wherever you want to access your configuration options.

The use will depend on whether you have added the Singleton=true entry to your .kcfgc file.

One the nicest features of the KConfig XT is its seamless integration with the Qt
Designer generated dialogs. You can do that by using KConfigDialog. The
steps to do that are as follows:

Create the KConfigDialog and pass the instance of your configuration data as one of the arguments. The construct would look like the following example:

KConfigDialog* dialog = new KConfigDialog(

this, "settings", YourAppSettings::self() );

assuming that YourAppSettings is the value of the ClassName variable from the kcfgc file and the settings class is a singelton.

In Qt Designer create widgets which should be used to configure your options. In order to make those widgets interact with the kcfg you have name each one of them using the following scheme:

Prefix the Name of the widget which should control one of the options with "kcfg_"

Append the "name" attribute value from your kcfg file which corresponds to option the given widget should control.

Add the Qt Designer generated widget to the KConfigDialog.

Show the dialog when you're done.

Example

Here's an example usage of KConfig XT for the application named Example.
With the following example.kcfg file:

To add a dialog you need to create a Qt Designer widget with the widget names
corresponding to the names of the options they should edit and prefixed with "kcfg_".
It could be something along the lines of:

And you can use the dialog with the following code:

//An instance of your dialog could be already created and could be
// cached, in which case you want to display the cached dialog
// instead of creating another one
if ( KConfigDialog::showDialog( "settings" ) )